Homogeneous metal-catalyzed exchange of aromatic compounds

4546

dium catalyst on charcoal is given by curve B of Figure 1. Rapid conversion is now initiated at a lower temperature with a peak resulting at 290". The thermograms were analyzed using the method of and gave an activation energy of 46 i 2 Piloyan, et kcal/mole for the uncatalyzed sample. This is in good accord with the value of 42.8 kcal/mole reported by Kistiakowsky and Smith. The palladium-catalyzed samples gave values of activation energy of 28 It 1.6 kcal/mole in agreement with the acceleration of the reaction by palladium reported by Urushibara and Simamura. 3 We are presently investigating several areas closely related to the stilbene case. These include the effect of aromatic substituents on the kinetic parameters and more general structure-reactivity relationships of these systems. The results of this work will appear in a future paper. Acknowledgment. We are indebted to the Research Foundation of the City University of New York for funds which made the above work possible. Angelo V. Santoro, Edward J. Barrett, Horst W. Hoyer Department of Chemistry, Hunter College of The City UniGersity of New York New York, New York 10021 Receiced June 19, 1967

Homogeneous Metal-Catalyzed Exchange of Aromatic Compounds. A New General Isotopic Hydrogen Labeling Procedure

Sir: We wish to report a simple one-step procedure for the exchange of hydrogen in isotopic water with a large number of aromatic compounds in the presence of

systems would thus support the concept that the chemistry of adsorbed molecules and the chemistry of inorganic coordination compounds are intimately related,2 presumably through r-complex formation. In addition to the catalytic implications of the present technique, the procedure constitutes a new, rapid, onestep method for labeling a large range of organic compounds with deuterium and/or tritium. It possesses a number of distinct advantages when compared with conventional procedures such as Wilzbach gas irradiation for tritium3 and heterogeneous exchange in solution, which is applicable to both hydrogen isotopes.'b In a typical procedure using the reagent quantities shown in Table I, a solution of acetic acid, heavy water, hydrochloric acid, the organic compound, and disodium platinum tetrachloride as catalyst is allowed to react in an evacuated sealed tube at a temperature within the range 25-120", this being determined by the isotope used and the enrichment required. All examples reported in the table utilize deuterium as the source of isotope since low-voltage mass spectrometry and nmr readily yield total isotope incorporation and orientation without the extensive chemical degradation necessitated by tritium. Acetic acid is essential to the medium to ensure homogeneity of phase. The acidity of the solution is critical, since this should be high enough t o stabilize the catalyst complex against reduction and thus prevent precipitation of platinum. However, the acidity should not be too high, otherwise the homogeneous metal-catalyzed process is inhibited and only acid exchange occurs in those compounds where this is possible. If platinum does precipitate from the reaction mixture it is found that the inorganic acid present poisons subsequent heterogeneous exchange on the surface of the precipitated catalyst. With certain compounds, such as mesitylene, where the ring hydrogens

Table I. Homogeneous Metal-Catalyzed Deuteration of Selected Aromatics

Compound

Weight, g

Benzene Fluorobenzene Chlorobenzene Toluene &Butylbenzene Trifluorotoluene Benzene Diphenyl Dibenzyl Naphthalene Phenanthrene Pyrene

0.176 0.205 0.221 0.173 0.173 0.238 0.088 0.100 0.100 0. 100 0.100 0.050

Media for

ex-

Temp, change" "C

A A A A A A B B B B B B

Exchange time, hr

Do

Di

4 4 4 4 4 3 2.3 2.3 2.3 2.3 0.85 0.7

82.2 87.6 87.1 84.6 87.6 92.8 87.8 83.0 83.5 75.3 80.7 85.4

2.6 3.1 3.0 4.1 3.1 1.35 1.65 3.0 3.8 20.4 16.2 13.7

82 82 82 82 82 80 75 75 75 75 75 75

Deuterium distribution, Dd Dz D3 2.8 3.6 3.7 4.4 4.4 1.95 1.65 4.0 4.6 3.3 1.4 1.0

2.9 4.0 6.0 4.8 5.0 3.85 1.85 5.5 5.5 0.6 0.25

Ds

Ds

3.1 1.5

3.5 0.2

2.9

1.1

0.7

0.4

2.05 1.7 1.1

2.40 1.3 0.7

2.70 1.5 0.5

z - deuteration 10.7b 5.9 5.7 4.7 5.4d 3.4 7.P 5.0 3.1 3.6 2.0 1.57

mole), Solution A: CH3COOD (1.00 mole), DzO (1.00 mole), KpPtClr (1.48 X a 2.0 ml of exchange media was used in each run. mole), and DCI (1.30 X low3 and DCI (1.48 X 10-3 mole); solution B: CH3COOD (1.00 mole), DzO (0.50 mole), Na2PtC1,(1.30 X Theoretical equilibrium for benzene, 85.7%. c 82.1 %. d Calculated assuming exchange in the aromatic portions only. mole).

homogeneous metal catalysts such as platinum(I1) salts. The results of this work are of importance t o fundamental catalysis since the present system constitutes the homogeneous analog of the conventional heterogeneous method which utilizes prereduced group VI11 transition metals as catalysts, platinum being the most active. A possible relationship between the two (1) (a) Part XXXVII of a series entitled "Catalytic Deuterium Ex-

Journal of the American Chemical Society

/

89:17

readily exchange under acid conditions, it is possible t o label both methyl and ring hydrogens in the molecule in one step by effecting a compromise in acidity such that both metal- and acid-catalyzed isotope incorporachange Reactions of Organics." Part XXXVI: G. E. Calf, B. D. Fisher, and J. L. Garnett, Australian J . Chem., in press. (b) J. L. Garnett and W. A. Sollich-Baumgartner, Aduan. Catalysis, 16,95 (1966). ( 2 ) M. Orchin, ibid., 16, l(1966). ( 3 ) K. E. Wilzbach, J . Am. Chem. Soc., 79, 1013 (1957).

1 August 16, 1967

4547 tion occur, although the efficiency of the two processes is reduced under these conditions. In the very large number of compounds that have been examined by the present technique, aromatics are generally quite reactive whereas aliphatics such as cyclohexane exchange very slowly. A representative number of compounds is included in Table I to illustrate the type of reactivity to be expected, the data being reported in such a manner as to indicate relative rates of reaction; thus relatively low exchange temperatures are shown together with low deuteration. If the temperature is raised t o 100-1 10” and the time of exchange increased slightly, equilibrium isotope incorporation is readily achieved in the active aromatic hydrogen positions of all compounds listed. A comparison of the rates of exchange of toluene and chlorobenzene (Table I) shows conclusively that the reaction is not acid catalyzed. The degree of exchange is not markedly influenced by the electronic character of the substituent (toluene us. trifluorotoluene). This conclusion is further supported by the isotope orientation in chlorobenzene, t-butylbenzene, and trifluorotoluene where the exchange is exclusively meta and para, as indicated by both the cutoff in the low-voltage mass spectrum and nmr data. For many of the monosubstituted benzenes, there is a remarkable similarity in isotope orientation between the present homogeneous platinum(I1) system and heterogeneous platinum-catalyzed e ~ c h a n g e . ~ For certain other compounds there are significant differences in exchange properties from the two procedures; thus as a potential isotopic hydrogen labeling tool it is predicted that the homogeneous technique will replace heterogeneous methods for many compounds and also act as a complementary procedure for the labeling of many others. A detailed summary of the advantages of the present procedure together with a discussion of the mechanistic implication of the work with respect to fundamental catalysis will be published in a series of papers elsewhere. Acknowledgment. The authors thank the Australian Research Grants Committee and the Australian Institute of Nuclear Science and Engineering for financial assistance. Acknowledgment is also made to the donors of the Petroleum Research Fund, administered by the American Chemical Society, for the support of this research. (4) R. R. Fraser and R. N. Renaud, J. Am. Chem. Soc., 88, 4365 (1966).

J. L. Garnett, R . J. Hodges Department of Physical Chemistry The Uniaersity of New South Wales Kensington, New South Wales, Australia Receiaed June 6, 1967

Contact and Solvent-Separated Ion Pairs of Carbanions. IV. Specific Solvation of Alkali Ions by Polyglycol Dimethyl Ethers Sir: We recently reported that variations in temperature and solvent composition caused reversible changes in the ultraviolet and visible absorption spectra of solutions of carbanions and radical anions. The changes, (1)

T.E. Hogen-Esch and J. Smid, J . Am. Chem. Soc., 88, 307

(1966).

0.0.

?

A (mp) I

320

I

340

I

I

1

360

380

400

Figure 1. Spectrum of F-,Li+ in mixtures of dioxane and CHaO(CHZCHZO)~CH~; [F-,Li+] = 1.4 X low8M . Curve 1 : pure dioxane; curves 2, 3, and 4 represent solutions with [PGDE] = 6.46 X M , 11.3 X M , and 24.3 X M , respectively.

showing distinctly separate absorption maxima (particularly pronounced with fluorenyl salts), were attributed to the existence of a rapid equilibrium between contact or intimate ion pairs (C-,M+) and solventseparated ion pairs (C-llM+). The ratio of the fractions of the two kinds of ion pairs was found to be a sensitive function of the basicity and geometrical structure of the solvating molecules. We have now investigated a series of polyglycol dimethyl ethers (PGDE) of the formula CHsO(CH2CH20),CH3 with respect to their behavior in solvating alkali cations. These molecules are expected to be powerful solvating agents because of the presence of multiple coordination sites within the same molec ~ l e . ~ , 3In our experiments, a solution of fluorenyllithium in dioxane (only contact ion pairs are observed in this solvent) was titrated under vacuum with a solution of the same salt in a mixture of dioxane and the respective polyglycol ether. The latter mixture was prepared so as to contain close to 100% solvent separated ion pairs. After each addition the optical spectrum was recorded. (With fluorenylsodium, some difficulties were encountered with dioxane as solvent, and T H F was therefore used.) An example involving triethylene glycol dimethyl ether is shown in Figure 1. The appearance of an isosbestic point confirms the stoichiometry of the reaction. The ratio of the fraction of the solvent-separated ion pair (371 mp) over that of the contact ion pair (345 mp) can be determined since the “pure” ion-pair spectra are known. Let us denote by n the number of PGDE mole(2) J. Ugeistad and 0. A. Rokstad, Acta Chem. Scund., 18, 474 (1964). (3) C. J. Pedersen, J. Am. Chem. Soc., 89,2495 (1967).

Communications to the Editor